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Representation of Symbolic Expressions in Mathematics

Representation of Symbolic Expressions in Mathematics. Jay McClelland Kevin Mickey Stanford University. Two Questions for Cognitive Science. What is thought? One Answer: Symbol processing What is symbol processing? One Answer:

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Representation of Symbolic Expressions in Mathematics

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  1. Representation of Symbolic Expressions in Mathematics Jay McClellandKevin MickeyStanford University

  2. Two Questions for Cognitive Science • What is thought? • One Answer: • Symbol processing • What is symbol processing? • One Answer: • Manipulation of structured ensembles of symbols according to structure sensitive rules

  3. A contemporary bit of linguistic structure

  4. A Brief History • The development of mathematical proof systems and (in the 19th century) formal logic created a mechanical method for deriving new valid expressions from other given expressions. • The creation of the digital computer (thanks to Turing and others) allows computers to implement these methods. • The promise of these methods lead to the creation of new disciplines: • artificial intelligence • cognitive psychology P → Q¬Q ¬P

  5. Herbert Simon, January 1953 • “Over the Christmas Holidays Alan Newell and I programmed a computer to think” • Their “logical theory machine” could prove simple theorems in propositional logic. • The system managed to prove 38 of the first 52 theorems of the Principia Mathematica

  6. MacSyma does the Math • The first comprehensive symbolic mathematics system was constructed between 1968 and 1982 • It provided a general purpose system for solving equations and carrying out mathematical computations • It was programmed in Lisp, a powerful symbol processing language • MacSyma contributed to the view (prevalent in the 1980’s still popular with some today) that Lisp is the ‘language of thought’

  7. But is human thinking really symbol manipulation? • Symbol processing could solve any solvable integro-differential equation, but could it • Recognize a face or a spoken word? • Understand a joke? • Use context, as people do, to resolve ambiguity • Go get me some RAID – the room is full of bugs • Could it come up with an insight or a creative solution to a novel problem?

  8. My Earlier Research • Explored neural networks as an alternative to the view that language and cognition involved symbol processing • Led to a debate that might be settled with a little more progress with deep neural nets

  9. But surely mathematical reasoning is symbolic! • “all mathematics is symbolic logic” (Russell, 1903)

  10. But some did not agree • “Draw a picture”

  11. The Symbolic Distance Effect 6 1 9

  12. A Proof of the Pythagorean Theorem Shephard, R.

  13. trigonometry

  14. cos(20-90) sin(20) -sin(20) cos(20) -cos(20)

  15. The Probes func(±k+Δ) func = sin or cos sign = +k or -k Δ = -180, -90, 0, 90, or 180 order = ±k+Δ or Δ±k k = random angle {10,20,30,40,50,60,70,80} Each type of probe appeared once in each block of 40 trials

  16. cos(180-40) sin(40) -sin(40) cos(40) -cos(40)

  17. A Sufficient Set of Rules • sin(x±180) = -sin(x) • cos(x±180) = -cos(x) • sin(-x) = -sin(x) • cos(-x) = cos(x) • sin(90-x)=cos(x) • plus some very simple algebra

  18. How often did you ______ ? sin(90–x) = cos(x) • use rules or formulas • visualize a right triangle • visualize the sine and cosine functions as waves • visualize a unit circle • use a mnemonic • other All Students Take Calculus Never Rarely Sometimes Often Always

  19. SelfReport Results

  20. Accuracy by Reported Circle Use

  21. sin(-x+0) and cos(-x+0)by reported circle use sin cos

  22. cos(70)

  23. cos(–70+0)

  24. It’s not just amount or recency

  25. Experiment 2 • Replicate! • No lesson • Find out what they had beentaught • Probe strategy problem by problem • Measure reaction times

  26. Expt 2 Results • Basic pattern replicates • Performance still depends on unit circle use controlling for unit circle exposure • But some self-described ‘unit circle’ users do not do well on cos(-x+0) or otherwise • Newfindings from RT and problem-specific strategy reports allow a deeper look at these cases

  27. General Circle Use, Speed and cos(-x+0)

  28. Specific Circle Use, Speed and cos(-x+0)

  29. Experiment 3 • Can we help participants use the unit circle? • Most said they had been taught it in their classes • In expt. 1, brief lessons half way through • Rules • Waves • But they had little effect • Experiment 3: • Unit circle lesson • Rules lesson • Expt. 2 as no-lesson control

  30. Effect of Unit Circle Lesson byPre-Lesson Performance

  31. Effect of Unit Circle Lesson vs. Rule Lesson

  32. Discussion • The right visualization strategy can make some problems easy, at least for many • But not everyone is a visual thinker • Why the unit circle works so well, why rules are so hard needs to be explored • More generally, we want to know: • Can we help people become visual thinkers? • Could that make them better mathematicians, scientists and engineers?

  33. What is thinking? What are Symbols? • Perhaps thinking is not always symbolic after all – not even mathematical thinking • Perhaps symbols are devices that evoke non-symbolic representations in the mind • 25 • cos(-70) • And maybe that’s what language comprehension and some other forms of thought are about as well

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